Employing artificial neural networks to find reaction coordinates and pathways for self-assembly

ChemRxiv : the preprint server for chemistry Pub Date : 2021-08-31 DOI:10.33774/chemrxiv-2021-9t07w

Jörn H Appeldorn, Simon Lemcke, T. Speck, A. Nikoubashman

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Abstract

Capturing the autonomous self-assembly of molecular building blocks in computer simulations is a persistent challenge, requiring to model complex interactions and to access long time scales. Advanced sampling methods allow to bridge these time scales but typically require to construct accurate low-dimensional representations of the transition pathways. In this work, we demonstrate for the self-assembly of two single-stranded DNA fragments into a ring-like structure how autoencoder architectures based on unsupervised neural networks can be employed to reliably expose transition pathways and to provide a suitable low-dimensional representation. The assembly occurs as a two-step process through two distinct half-bound states, which are correctly identified by the neural net. We exploit this latent space representation to construct a Markov state model for predicting the four molecular conformations and transition rates. Our work opens up new avenues for the computational modeling of multi-step and hierarchical self-assembly, which has proven challenging so far.

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利用人工神经网络寻找自组装的反应坐标和途径

在计算机模拟中捕捉分子构建块的自主自组装是一个持续的挑战，需要对复杂的相互作用进行建模并访问长时间尺度。先进的采样方法允许桥接这些时间尺度，但通常需要构建过渡路径的精确低维表示。在这项工作中，我们展示了如何将两个单链DNA片段自组装成环状结构，从而使用基于无监督神经网络的自动编码器架构来可靠地暴露过渡路径并提供合适的低维表示。组装是通过两个不同的半束缚状态进行的两步过程，这两个状态由神经网络正确识别。我们利用这种潜在空间表示来构建一个马尔可夫状态模型，用于预测四种分子构象和跃迁速率。我们的工作为多步骤和分级自组装的计算建模开辟了新的途径，迄今为止，这已被证明是具有挑战性的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ChemRxiv : the preprint server for chemistry

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